#include "yolo4_layer.h"
#include "activations.h"
#include "blas.h"
#include "box.h"
#include "opencl.h"
#include "utils.h"

#include <math.h>
#include <stdio.h>
#include <assert.h>
#include <string.h>
#include <stdlib.h>

layer make_yolo4_layer(int batch, int w, int h, int n, int total, int *mask, int classes, int max_boxes,int is_yolo4)
{
    int i;
    layer l = { (LAYER_TYPE)0 };
    l.type = YOLO4;

    l.n = n;
    l.total = total;
    l.batch = batch;
    l.h = h;
    l.w = w;
    l.c = n*(classes + 4 + 1);
    l.out_w = l.w;
    l.out_h = l.h;
    l.out_c = l.c;
    l.classes = classes;
    l.cost = (float*)calloc(1, sizeof(float));
    l.biases = (float*)calloc(total*2, sizeof(float));
    if(mask) l.mask = mask;
    else{
        l.mask = (int*)calloc(n, sizeof(int));
        for(i = 0; i < n; ++i){
            l.mask[i] = i;
        }
    }
    l.bias_updates = (float*)calloc(n*2, sizeof(float));
    l.outputs = h*w*n*(classes + 4 + 1);
    l.inputs = l.outputs;
    l.max_boxes = max_boxes;
    l.truth_size = 4 + 1;
    l.truths = l.max_boxes*l.truth_size;    // 90*(4 + 1);
    l.labels = (int*)calloc(batch*l.w*l.h*l.n, sizeof(int));
    for (i = 0; i < batch*l.w*l.h*l.n; ++i) l.labels[i] = -1;
    l.class_ids = (int*)calloc(batch*l.w*l.h*l.n, sizeof(int));
    for (i = 0; i < batch*l.w*l.h*l.n; ++i) l.class_ids[i] = -1;

    l.delta = (float*)calloc(batch * l.outputs, sizeof(float));
    l.output = (float*)calloc(batch * l.outputs, sizeof(float));
    l.output_avg = (float*)calloc(batch * l.outputs, sizeof(float));

    for(i = 0; i < total*2; ++i){
        l.biases[i] = .5;
    }

    l.forward = forward_yolo4_layer;
    l.backward = backward_yolo4_layer;

#ifdef GPU
    if (gpu_index >= 0) {
        if(is_yolo4) l.forward_gpu = forward_yolo4_layer_gpu;
        else l.forward_gpu = forward_yolo7_layer_gpu;
        l.backward_gpu = backward_yolo4_layer_gpu;
        l.update_gpu = 0;
        l.output_gpu = opencl_make_array(l.output, batch*l.outputs);
        l.delta_gpu = opencl_make_array(l.delta, batch*l.outputs);
        l.output_avg_gpu = opencl_make_array(l.output_avg, batch*l.outputs);

    }
#endif

    fprintf(stderr, "yolo4\n");
    srand(time(0));

    return l;
}

void resize_yolo4_layer(layer *l, int w, int h) {
    l->w = w;
    l->h = h;

    l->outputs = h*w*l->n*(l->classes + 4 + 1);
    l->inputs = l->outputs;

#ifdef GPU
    if (gpu_index >= 0) {
        opencl_free_gpu_only(l->delta_gpu);
        opencl_free_gpu_only(l->output_gpu);
        opencl_free_gpu_only(l->output_avg_gpu);
    }
#endif

    if (l->labels) l->labels = (int*)realloc(l->labels, l->batch*l->n*l->h*l->w*sizeof(int));
    if (l->class_ids) l->class_ids = (int*)realloc(l->class_ids, l->batch*l->n*l->h*l->w*sizeof(int));

    l->output = (float*)realloc(l->output,l->batch*l->outputs*sizeof(float));
    l->delta = (float*)realloc(l->delta,l->batch*l->outputs*sizeof(float));
    l->output_avg = (float*)realloc(l->output_avg, l->batch*l->outputs*sizeof(float));

#ifdef GPU
    if (gpu_index >= 0) {
        l->output_gpu = opencl_make_array(l->output, l->batch*l->outputs);
        l->delta_gpu = opencl_make_array(l->delta, l->batch*l->outputs);
        l->output_avg_gpu = opencl_make_array(l->output_avg, l->batch*l->outputs);
    }
#endif
}

box get_yolo4_box(float *x, float *biases, int n, int index, int i, int j, int lw, int lh, int w, int h, int stride, int new_coords)
{
    box b;
    // ln - natural logarithm (base = e)
    // x` = t.x*lw - i;   // x = ln(x`/(1-x`))   // x - output of previous conv-layer
    // y` = t.y*lh - i;   // y = ln(y`/(1-y`))   // y - output of previous conv-layer
    // w = ln(t.w*net.w / anchors_w); // w - output of previous conv-layer
    // h = ln(t.h*net.h / anchors_h); // h - output of previous conv-layer
    if (new_coords) {
        b.x = (i + x[index + 0*stride]) / lw;
        b.y = (j + x[index + 1*stride]) / lh;
        b.w = x[index + 2*stride]*x[index + 2*stride]*4*biases[2*n] / w;
        b.h = x[index + 3*stride]*x[index + 3*stride]*4*biases[2*n + 1] / h;
    }
    else {
        b.x = (i + x[index + 0*stride]) / lw;
        b.y = (j + x[index + 1*stride]) / lh;
        b.w = exp(x[index + 2*stride])*biases[2*n] / w;
        b.h = exp(x[index + 3*stride])*biases[2*n + 1] / h;
    }
    return b;
}

static inline float fix_nan_inf(float val)
{
    if (isnan(val) || isinf(val)) val = 0;
    return val;
}

static inline float clip_value(float val, const float max_val)
{
    if (val > max_val) {
        //printf("\n val = %f > max_val = %f \n", val, max_val);
        val = max_val;
    }
    else if (val < -max_val) {
        //printf("\n val = %f < -max_val = %f \n", val, -max_val);
        val = -max_val;
    }
    return val;
}

ious delta_yolo4_box(box truth, float *x, float *biases, int n, int index, int i, int j, int lw, int lh, int w, int h, float *delta, float scale, int stride, float iou_normalizer, IOU_LOSS iou_loss, int accumulate, float max_delta, int *rewritten_bbox, int new_coords)
{
    if (delta[index + 0*stride] || delta[index + 1*stride] || delta[index + 2*stride] || delta[index + 3*stride]) {
        (*rewritten_bbox)++;
    }

    ious all_ious = { 0 };
    // i - step in layer width
    // j - step in layer height
    //  Returns a box in absolute coordinates
    box pred = get_yolo4_box(x, biases, n, index, i, j, lw, lh, w, h, stride, new_coords);
    all_ious.iou = box_iou_y4(pred, truth);
    all_ious.giou = box_giou_y4(pred, truth);
    all_ious.diou = box_diou_y4(pred, truth);
    all_ious.ciou = box_ciou_y4(pred, truth);
    // avoid nan in dx_box_iou
    if (pred.w == 0) { pred.w = 1.0; }
    if (pred.h == 0) { pred.h = 1.0; }
    if (iou_loss == MSE)    // old loss
    {
        float tx = (truth.x*lw - i);
        float ty = (truth.y*lh - j);
        float tw = log(truth.w*w / biases[2*n]);
        float th = log(truth.h*h / biases[2*n + 1]);

        //printf(" tx = %f, ty = %f, tw = %f, th = %f \n", tx, ty, tw, th);
        //printf(" x = %f, y = %f, w = %f, h = %f \n", x[index + 0*stride], x[index + 1*stride], x[index + 2*stride], x[index + 3*stride]);

        // accumulate delta
        delta[index + 0*stride] += scale*(tx - x[index + 0*stride])*iou_normalizer;
        delta[index + 1*stride] += scale*(ty - x[index + 1*stride])*iou_normalizer;
        delta[index + 2*stride] += scale*(tw - x[index + 2*stride])*iou_normalizer;
        delta[index + 3*stride] += scale*(th - x[index + 3*stride])*iou_normalizer;
    }
    else {
        // https://github.com/generalized-iou/g-darknet
        // https://arxiv.org/abs/1902.09630v2
        // https://giou.stanford.edu/
        all_ious.dx_iou = dx_box_iou_y4(pred, truth, iou_loss);

        // jacobian^t (transpose)
        //float dx = (all_ious.dx_iou.dl + all_ious.dx_iou.dr);
        //float dy = (all_ious.dx_iou.dt + all_ious.dx_iou.db);
        //float dw = ((-0.5*all_ious.dx_iou.dl) + (0.5*all_ious.dx_iou.dr));
        //float dh = ((-0.5*all_ious.dx_iou.dt) + (0.5*all_ious.dx_iou.db));

        // jacobian^t (transpose)
        float dx = all_ious.dx_iou.dt;
        float dy = all_ious.dx_iou.db;
        float dw = all_ious.dx_iou.dl;
        float dh = all_ious.dx_iou.dr;

        // predict exponential, apply gradient of e^delta_t ONLY for w,h
        dw *= exp(x[index + 2*stride]);
        dh *= exp(x[index + 3*stride]);

        // normalize iou weight
        dx *= iou_normalizer;
        dy *= iou_normalizer;
        dw *= iou_normalizer;
        dh *= iou_normalizer;

        dx = fix_nan_inf(dx);
        dy = fix_nan_inf(dy);
        dw = fix_nan_inf(dw);
        dh = fix_nan_inf(dh);

        if (max_delta != FLT_MAX) {
            dx = clip_value(dx, max_delta);
            dy = clip_value(dy, max_delta);
            dw = clip_value(dw, max_delta);
            dh = clip_value(dh, max_delta);
        }

        if (!accumulate) {
            delta[index + 0*stride] = 0;
            delta[index + 1*stride] = 0;
            delta[index + 2*stride] = 0;
            delta[index + 3*stride] = 0;
        }

        // accumulate delta
        delta[index + 0*stride] += dx;
        delta[index + 1*stride] += dy;
        delta[index + 2*stride] += dw;
        delta[index + 3*stride] += dh;
    }

    return all_ious;
}

void averages_yolo4_deltas(int class_index, int box_index, int stride, int classes, float *delta)
{

    int classes_in_one_box = 0;
    int c;
    for (c = 0; c < classes; ++c) {
        if (delta[class_index + stride*c] > 0) classes_in_one_box++;
    }

    if (classes_in_one_box > 0) {
        delta[box_index + 0*stride] /= classes_in_one_box;
        delta[box_index + 1*stride] /= classes_in_one_box;
        delta[box_index + 2*stride] /= classes_in_one_box;
        delta[box_index + 3*stride] /= classes_in_one_box;
    }
}

void delta_yolo4_class(float *output, float *delta, int index, int class_id, int classes, int stride, float *avg_cat, int focal_loss, float label_smooth_eps, float *classes_multipliers, float cls_normalizer)
{
    int n;
    if (delta[index]){
        delta[index + stride*class_id] = 1 - output[index + stride*class_id];
        if(avg_cat) *avg_cat += output[index + stride*class_id];
        return;
    }
    for(n = 0; n < classes; ++n){
        delta[index + stride*n] = ((n == class_id)?1 : 0) - output[index + stride*n];
        if(n == class_id && avg_cat) *avg_cat += output[index + stride*n];
    }
    /*
    int n;
    if (delta[index + stride*class_id]){
        float y_true = 1;
        if(label_smooth_eps) y_true = y_true* (1 - label_smooth_eps) + 0.5*label_smooth_eps;
        float result_delta = y_true - output[index + stride*class_id];
        if(!isnan(result_delta) && !isinf(result_delta)) delta[index + stride*class_id] = result_delta;
        //delta[index + stride*class_id] = 1 - output[index + stride*class_id];

        if (classes_multipliers) delta[index + stride*class_id] *= classes_multipliers[class_id];
        if(avg_cat) *avg_cat += output[index + stride*class_id];
        return;
    }
    // Focal loss
    if (focal_loss) {
        // Focal Loss
        float alpha = 0.5;    // 0.25 or 0.5
        //float gamma = 2;    // hardcoded in many places of the grad-formula

        int ti = index + stride*class_id;
        float pt = output[ti] + 0.000000000000001F;
        // http://fooplot.com/#W3sidHlwZSI6MCwiZXEiOiItKDEteCkqKDIqeCpsb2coeCkreC0xKSIsImNvbG9yIjoiIzAwMDAwMCJ9LHsidHlwZSI6MTAwMH1d
        float grad = -(1 - pt)*(2*pt*logf(pt) + pt - 1);    // http://blog.csdn.net/linmingan/article/details/77885832
        //float grad = (1 - pt)*(2*pt*logf(pt) + pt - 1);    // https://github.com/unsky/focal-loss

        for (n = 0; n < classes; ++n) {
            delta[index + stride*n] = (((n == class_id) ? 1 : 0) - output[index + stride*n]);

            delta[index + stride*n] *= alpha*grad;

            if (n == class_id && avg_cat) *avg_cat += output[index + stride*n];
        }
    }
    else {
        // default
        for (n = 0; n < classes; ++n) {
            float y_true = ((n == class_id) ? 1 : 0);
            if (label_smooth_eps) y_true = y_true* (1 - label_smooth_eps) + 0.5*label_smooth_eps;
            float result_delta = y_true - output[index + stride*n];
            if (!isnan(result_delta) && !isinf(result_delta)) delta[index + stride*n] = result_delta;

            if (classes_multipliers && n == class_id) delta[index + stride*class_id] *= classes_multipliers[class_id]*cls_normalizer;
            if (n == class_id && avg_cat) *avg_cat += output[index + stride*n];
        }
    }
    */
}

int compare_yolo4_class(float *output, int classes, int class_index, int stride, float objectness, int class_id, float conf_thresh)
{
    int j;
    for (j = 0; j < classes; ++j) {
        //float prob = objectness*output[class_index + stride*j];
        float prob = output[class_index + stride*j];
        if (prob > conf_thresh) {
            return 1;
        }
    }
    return 0;
}

typedef struct train_yolo4_args {
    layer l;
    network net;
    int b;
    float tot_iou;
    float tot_giou_loss;
    float tot_iou_loss;
    int count;
    int class_count;
} train_yolo4_args;

void *process_batch(void* ptr)
{
    {
        train_yolo4_args *args = (train_yolo4_args*)ptr;
        const layer l = args->l;
        network net = args->net;
        int b = args->b;

        int i, j, t, n;

        //printf(" b = %d \n", b, b);

        //float tot_iou = 0;
        float tot_giou = 0;
        float tot_diou = 0;
        float tot_ciou = 0;
        //float tot_iou_loss = 0;
        //float tot_giou_loss = 0;
        float tot_diou_loss = 0;
        float tot_ciou_loss = 0;
        float recall = 0;
        float recall75 = 0;
        float avg_cat = 0;
        float avg_obj = 0;
        float avg_anyobj = 0;
        //int count = 0;
        //int class_count = 0;

        for (j = 0; j < l.h; ++j) {
            for (i = 0; i < l.w; ++i) {
                for (n = 0; n < l.n; ++n) {
                    const int class_index = entry_index(l, b, n*l.w*l.h + j*l.w + i, 4 + 1);
                    const int obj_index = entry_index(l, b, n*l.w*l.h + j*l.w + i, 4);
                    const int box_index = entry_index(l, b, n*l.w*l.h + j*l.w + i, 0);
                    const int stride = l.w*l.h;
                    box pred = get_yolo4_box(l.output, l.biases, l.mask[n], box_index, i, j, l.w, l.h, net.w, net.h, l.w*l.h, l.new_coords);
                    float best_match_iou = 0;
                    int best_match_t = 0;
                    float best_iou = 0;
                    int best_t = 0;
                    for (t = 0; t < l.max_boxes; ++t) {
                        box truth = float_to_box_stride_y4(net.truth + t*l.truth_size + b*l.truths, 1);
                        if (!truth.x) break;  // continue;
                        int class_id = net.truth[t*l.truth_size + b*l.truths + 4];
                        if (class_id >= l.classes || class_id < 0) {
                            printf("\n Warning: in txt-labels class_id=%d >= classes=%d in cfg-file. In txt-labels class_id should be [from 0 to %d] \n", class_id, l.classes, l.classes - 1);
                            printf("\n truth.x = %f, truth.y = %f, truth.w = %f, truth.h = %f, class_id = %d \n", truth.x, truth.y, truth.w, truth.h, class_id);
                            continue; // if label contains class_id more than number of classes in the cfg-file and class_id check garbage value
                        }

                        float objectness = l.output[obj_index];
                        if (isnan(objectness) || isinf(objectness)) l.output[obj_index] = 0;
                        int class_id_match = compare_yolo4_class(l.output, l.classes, class_index, l.w*l.h, objectness, class_id, 0.25f);

                        float iou = box_iou_y4(pred, truth);
                        if (iou > best_match_iou && class_id_match == 1) {
                            best_match_iou = iou;
                            best_match_t = t;
                        }
                        if (iou > best_iou) {
                            best_iou = iou;
                            best_t = t;
                        }
                    }

                    avg_anyobj += l.output[obj_index];
                    l.delta[obj_index] = l.obj_normalizer*(0 - l.output[obj_index]);
                    if (best_match_iou > l.ignore_thresh) {
                        if (l.objectness_smooth) {
                            const float delta_obj = l.obj_normalizer*(best_match_iou - l.output[obj_index]);
                            if (delta_obj > l.delta[obj_index]) l.delta[obj_index] = delta_obj;

                        }
                        else l.delta[obj_index] = 0;
                    }
                    else if (net.adversarial) {
                        int stride = l.w*l.h;
                        float scale = pred.w*pred.h;
                        if (scale > 0) scale = sqrt(scale);
                        l.delta[obj_index] = scale*l.obj_normalizer*(0 - l.output[obj_index]);
                        int cl_id;
                        int found_object = 0;
                        for (cl_id = 0; cl_id < l.classes; ++cl_id) {
                            if (l.output[class_index + stride*cl_id]*l.output[obj_index] > 0.25) {
                                l.delta[class_index + stride*cl_id] = scale*(0 - l.output[class_index + stride*cl_id]);
                                found_object = 1;
                            }
                        }
                        if (found_object) {
                            // don't use this loop for adversarial attack drawing
                            for (cl_id = 0; cl_id < l.classes; ++cl_id)
                                if (l.output[class_index + stride*cl_id]*l.output[obj_index] < 0.25)
                                    l.delta[class_index + stride*cl_id] = scale*(1 - l.output[class_index + stride*cl_id]);

                                l.delta[box_index + 0*stride] += scale*(0 - l.output[box_index + 0*stride]);
                                l.delta[box_index + 1*stride] += scale*(0 - l.output[box_index + 1*stride]);
                                l.delta[box_index + 2*stride] += scale*(0 - l.output[box_index + 2*stride]);
                                l.delta[box_index + 3*stride] += scale*(0 - l.output[box_index + 3*stride]);
                        }
                    }
                    if (best_iou > l.truth_thresh) {
                        const float iou_multiplier = best_iou*best_iou;// (best_iou - l.truth_thresh) / (1.0 - l.truth_thresh);
                        if (l.objectness_smooth) l.delta[obj_index] = l.obj_normalizer*(iou_multiplier - l.output[obj_index]);
                        else l.delta[obj_index] = l.obj_normalizer*(1 - l.output[obj_index]);
                        //l.delta[obj_index] = l.obj_normalizer*(1 - l.output[obj_index]);

                        int class_id = net.truth[best_t*l.truth_size + b*l.truths + 4];
                        if (l.map) class_id = l.map[class_id];
                        delta_yolo4_class(l.output, l.delta, class_index, class_id, l.classes, l.w*l.h, 0, l.focal_loss, l.label_smooth_eps, l.classes_multipliers, l.cls_normalizer);
                        const float class_multiplier = (l.classes_multipliers) ? l.classes_multipliers[class_id] : 1.0f;
                        if (l.objectness_smooth) l.delta[class_index + stride*class_id] = class_multiplier*(iou_multiplier - l.output[class_index + stride*class_id]);
                        box truth = float_to_box_stride_y4(net.truth + best_t*l.truth_size + b*l.truths, 1);
                        delta_yolo4_box(truth, l.output, l.biases, l.mask[n], box_index, i, j, l.w, l.h, net.w, net.h, l.delta, (2 - truth.w*truth.h), l.w*l.h, l.iou_normalizer*class_multiplier, l.iou_loss, 1, l.max_delta, net.rewritten_bbox, l.new_coords);
                        (*net.total_bbox)++;
                    }
                }
            }
        }
        for (t = 0; t < l.max_boxes; ++t) {
            box truth = float_to_box_stride_y4(net.truth + t*l.truth_size + b*l.truths, 1);
            if (!truth.x) break;  // continue;
            if (truth.x < 0 || truth.y < 0 || truth.x > 1 || truth.y > 1 || truth.w < 0 || truth.h < 0) {
                char buff[256];
                printf(" Wrong label: truth.x = %f, truth.y = %f, truth.w = %f, truth.h = %f \n", truth.x, truth.y, truth.w, truth.h);
                sprintf(buff, "echo \"Wrong label: truth.x = %f, truth.y = %f, truth.w = %f, truth.h = %f\" >> bad_label.list",
                        truth.x, truth.y, truth.w, truth.h);
                system(buff);
            }
            int class_id = net.truth[t*l.truth_size + b*l.truths + 4];
            if (class_id >= l.classes || class_id < 0) continue; // if label contains class_id more than number of classes in the cfg-file and class_id check garbage value

            float best_iou = 0;
            int best_n = 0;
            i = (truth.x*l.w);
            j = (truth.y*l.h);
            box truth_shift = truth;
            truth_shift.x = truth_shift.y = 0;
            for (n = 0; n < l.total; ++n) {
                box pred = { 0 };
                pred.w = l.biases[2*n] / net.w;
                pred.h = l.biases[2*n + 1] / net.h;
                float iou = box_iou(pred, truth_shift);
                if (iou > best_iou) {
                    best_iou = iou;
                    best_n = n;
                }
            }

            int mask_n = int_index(l.mask, best_n, l.n);
            if (mask_n >= 0) {
                int class_id = net.truth[t*l.truth_size + b*l.truths + 4];
                if (l.map) class_id = l.map[class_id];

                int box_index = entry_index(l, b, mask_n*l.w*l.h + j*l.w + i, 0);
                const float class_multiplier = (l.classes_multipliers) ? l.classes_multipliers[class_id] : 1.0f;
                ious all_ious = delta_yolo4_box(truth, l.output, l.biases, best_n, box_index, i, j, l.w, l.h, net.w, net.h, l.delta, (2 - truth.w*truth.h), l.w*l.h, l.iou_normalizer*class_multiplier, l.iou_loss, 1, l.max_delta, net.rewritten_bbox, l.new_coords);
                (*net.total_bbox)++;

                const int truth_in_index = t*l.truth_size + b*l.truths + 5;
                const int track_id = net.truth[truth_in_index];
                const int truth_out_index = b*l.n*l.w*l.h + mask_n*l.w*l.h + j*l.w + i;
                l.labels[truth_out_index] = track_id;
                l.class_ids[truth_out_index] = class_id;
                //printf(" track_id = %d, t = %d, b = %d, truth_in_index = %d, truth_out_index = %d \n", track_id, t, b, truth_in_index, truth_out_index);

                // range is 0 <= 1
                args->tot_iou += all_ious.iou;
                args->tot_iou_loss += 1 - all_ious.iou;
                // range is -1 <= giou <= 1
                tot_giou += all_ious.giou;
                args->tot_giou_loss += 1 - all_ious.giou;

                tot_diou += all_ious.diou;
                tot_diou_loss += 1 - all_ious.diou;

                tot_ciou += all_ious.ciou;
                tot_ciou_loss += 1 - all_ious.ciou;

                int obj_index = entry_index(l, b, mask_n*l.w*l.h + j*l.w + i, 4);
                avg_obj += l.output[obj_index];
                if (l.objectness_smooth) {
                    float delta_obj = class_multiplier*l.obj_normalizer*(1 - l.output[obj_index]);
                    if (l.delta[obj_index] == 0) l.delta[obj_index] = delta_obj;
                }
                else l.delta[obj_index] = class_multiplier*l.obj_normalizer*(1 - l.output[obj_index]);

                int class_index = entry_index(l, b, mask_n*l.w*l.h + j*l.w + i, 4 + 1);
                delta_yolo4_class(l.output, l.delta, class_index, class_id, l.classes, l.w*l.h, &avg_cat, l.focal_loss, l.label_smooth_eps, l.classes_multipliers, l.cls_normalizer);

                //printf(" label: class_id = %d, truth.x = %f, truth.y = %f, truth.w = %f, truth.h = %f \n", class_id, truth.x, truth.y, truth.w, truth.h);
                //printf(" mask_n = %d, l.output[obj_index] = %f, l.output[class_index + class_id] = %f \n\n", mask_n, l.output[obj_index], l.output[class_index + class_id]);

                ++(args->count);
                ++(args->class_count);
                if (all_ious.iou > .5) recall += 1;
                if (all_ious.iou > .75) recall75 += 1;
            }

            // iou_thresh
            for (n = 0; n < l.total; ++n) {
                int mask_n = int_index(l.mask, n, l.n);
                if (mask_n >= 0 && n != best_n && l.iou_thresh < 1.0f) {
                    box pred = { 0 };
                    pred.w = l.biases[2*n] / net.w;
                    pred.h = l.biases[2*n + 1] / net.h;
                    float iou = box_iou_kind(pred, truth_shift, l.iou_thresh_kind); // IOU, GIOU, MSE, DIOU, CIOU
                    // iou, n

                    if (iou > l.iou_thresh) {
                        int class_id = net.truth[t*l.truth_size + b*l.truths + 4];
                        if (l.map) class_id = l.map[class_id];

                        int box_index = entry_index(l, b, mask_n*l.w*l.h + j*l.w + i, 0);
                        const float class_multiplier = (l.classes_multipliers) ? l.classes_multipliers[class_id] : 1.0f;
                        ious all_ious = delta_yolo4_box(truth, l.output, l.biases, n, box_index, i, j, l.w, l.h, net.w, net.h, l.delta, (2 - truth.w*truth.h), l.w*l.h, l.iou_normalizer*class_multiplier, l.iou_loss, 1, l.max_delta, net.rewritten_bbox, l.new_coords);
                        (*net.total_bbox)++;

                        // range is 0 <= 1
                        args->tot_iou += all_ious.iou;
                        args->tot_iou_loss += 1 - all_ious.iou;
                        // range is -1 <= giou <= 1
                        tot_giou += all_ious.giou;
                        args->tot_giou_loss += 1 - all_ious.giou;

                        tot_diou += all_ious.diou;
                        tot_diou_loss += 1 - all_ious.diou;

                        tot_ciou += all_ious.ciou;
                        tot_ciou_loss += 1 - all_ious.ciou;

                        int obj_index = entry_index(l, b, mask_n*l.w*l.h + j*l.w + i, 4);
                        avg_obj += l.output[obj_index];
                        if (l.objectness_smooth) {
                            float delta_obj = class_multiplier*l.obj_normalizer*(1 - l.output[obj_index]);
                            if (l.delta[obj_index] == 0) l.delta[obj_index] = delta_obj;
                        }
                        else l.delta[obj_index] = class_multiplier*l.obj_normalizer*(1 - l.output[obj_index]);

                        int class_index = entry_index(l, b, mask_n*l.w*l.h + j*l.w + i, 4 + 1);
                        delta_yolo4_class(l.output, l.delta, class_index, class_id, l.classes, l.w*l.h, &avg_cat, l.focal_loss, l.label_smooth_eps, l.classes_multipliers, l.cls_normalizer);

                        ++(args->count);
                        ++(args->class_count);
                        if (all_ious.iou > .5) recall += 1;
                        if (all_ious.iou > .75) recall75 += 1;
                    }
                }
            }
        }

        if (l.iou_thresh < 1.0f) {
            // averages the deltas obtained by the function: delta_yolo4_box()_accumulate
            for (j = 0; j < l.h; ++j) {
                for (i = 0; i < l.w; ++i) {
                    for (n = 0; n < l.n; ++n) {
                        int obj_index = entry_index(l, b, n*l.w*l.h + j*l.w + i, 4);
                        int box_index = entry_index(l, b, n*l.w*l.h + j*l.w + i, 0);
                        int class_index = entry_index(l, b, n*l.w*l.h + j*l.w + i, 4 + 1);
                        const int stride = l.w*l.h;

                        if (l.delta[obj_index] != 0)
                            averages_yolo4_deltas(class_index, box_index, stride, l.classes, l.delta);
                    }
                }
            }
        }

    }

    return 0;
}

void forward_yolo4_layer(const layer l, network net)
{
    //int i, j, b, t, n;
    memcpy(l.output, net.input, l.outputs*l.batch*sizeof(float));
    int b, n;

#ifndef GPU
    for (b = 0; b < l.batch; ++b) {
        for (n = 0; n < l.n; ++n) {
            int bbox_index = entry_index(l, b, n*l.w*l.h, 0);
            if (l.new_coords) {
                //activate_array(l.output + bbox_index, 4*l.w*l.h, LOGISTIC);    // x,y,w,h
            }
            else {
                activate_array(l.output + bbox_index, 2*l.w*l.h, LOGISTIC);        // x,y,
                int obj_index = entry_index(l, b, n*l.w*l.h, 4);
                activate_array(l.output + obj_index, (1 + l.classes)*l.w*l.h, LOGISTIC);
            }
            scal_add_cpu(2*l.w*l.h, l.scale_x_y, -0.5*(l.scale_x_y - 1), l.output + bbox_index, 1);    // scale x,y
        }
    }
#endif

// delta is zeroed
memset(l.delta, 0, l.outputs*l.batch*sizeof(float));
    if (!net.train) return;

    int i;
    for (i = 0; i < l.batch*l.w*l.h*l.n; ++i) l.labels[i] = -1;
    for (i = 0; i < l.batch*l.w*l.h*l.n; ++i) l.class_ids[i] = -1;
    //float avg_iou = 0;
    float tot_iou = 0;
    float tot_giou = 0;
    float tot_diou = 0;
    float tot_ciou = 0;
    float tot_iou_loss = 0;
    float tot_giou_loss = 0;
    float tot_diou_loss = 0;
    float tot_ciou_loss = 0;
    float recall = 0;
    float recall75 = 0;
    float avg_cat = 0;
    float avg_obj = 0;
    float avg_anyobj = 0;
    int count = 0;
    int class_count = 0;
    *(l.cost) = 0;


    int num_threads = l.batch;
    pthread_t* threads = (pthread_t*)calloc(num_threads, sizeof(pthread_t));

    struct train_yolo4_args* yolo4_args = (train_yolo4_args*)calloc(l.batch, sizeof(struct train_yolo4_args));

    for (b = 0; b < l.batch; b++)
    {
        yolo4_args[b].l = l;
        yolo4_args[b].net = net;
        yolo4_args[b].b = b;

        yolo4_args[b].tot_iou = 0;
        yolo4_args[b].tot_iou_loss = 0;
        yolo4_args[b].tot_giou_loss = 0;
        yolo4_args[b].count = 0;
        yolo4_args[b].class_count = 0;

        if (pthread_create(&threads[b], 0, process_batch, &(yolo4_args[b]))) error("Thread creation failed");
    }

    for (b = 0; b < l.batch; b++)
    {
        pthread_join(threads[b], 0);

        tot_iou += yolo4_args[b].tot_iou;
        tot_iou_loss += yolo4_args[b].tot_iou_loss;
        tot_giou_loss += yolo4_args[b].tot_giou_loss;
        count += yolo4_args[b].count;
        class_count += yolo4_args[b].class_count;
    }

    free(yolo4_args);
    free(threads);

    // Search for an equidistant point from the distant boundaries of the local minimum
    int iteration_num = get_current_iteration(net);
    const int start_point = net.max_batches*3 / 4;
    //printf(" equidistant_point ep = %d, it = %d \n", net.equidistant_point, iteration_num);

    if (count == 0) count = 1;
    if (class_count == 0) class_count = 1;

    if (l.show_details == 0) {
        float loss = pow(mag_array(l.delta, l.outputs*l.batch), 2);
        *(l.cost) = loss;

        loss /= l.batch;

        fprintf(stderr, "v3 (%s loss, Normalizer: (iou: %.2f, obj: %.2f, cls: %.2f) Region %d Avg (IOU: %f), count: %d, total_loss = %f \n",
                (l.iou_loss == MSE ? "mse" : (l.iou_loss == GIOU ? "giou" : "iou")), l.iou_normalizer, l.obj_normalizer, l.cls_normalizer, net.index, tot_iou / count, count, loss);
    }
    else {
        // show detailed output

        int stride = l.w*l.h;
        float* no_iou_loss_delta = (float *)calloc(l.batch*l.outputs, sizeof(float));
        memcpy(no_iou_loss_delta, l.delta, l.batch*l.outputs*sizeof(float));


        int j, n;
        for (b = 0; b < l.batch; ++b) {
            for (j = 0; j < l.h; ++j) {
                for (i = 0; i < l.w; ++i) {
                    for (n = 0; n < l.n; ++n) {
                        int index = entry_index(l, b, n*l.w*l.h + j*l.w + i, 0);
                        no_iou_loss_delta[index + 0*stride] = 0;
                        no_iou_loss_delta[index + 1*stride] = 0;
                        no_iou_loss_delta[index + 2*stride] = 0;
                        no_iou_loss_delta[index + 3*stride] = 0;
                    }
                }
            }
        }

        float classification_loss = l.obj_normalizer*pow(mag_array(no_iou_loss_delta, l.outputs*l.batch), 2);
        free(no_iou_loss_delta);
        float loss = pow(mag_array(l.delta, l.outputs*l.batch), 2);
        float iou_loss = loss - classification_loss;

        float avg_iou_loss = 0;
        *(l.cost) = loss;

        // gIOU loss + MSE (objectness) loss
        if (l.iou_loss == MSE) {
            *(l.cost) = pow(mag_array(l.delta, l.outputs*l.batch), 2);
        }
        else {
            // Always compute classification loss both for iou + cls loss and for logging with mse loss
            // TODO: remove IOU loss fields before computing MSE on class
            //   probably split into two arrays
            if (l.iou_loss == GIOU) {
                avg_iou_loss = count > 0 ? l.iou_normalizer*(tot_giou_loss / count) : 0;
            }
            else {
                avg_iou_loss = count > 0 ? l.iou_normalizer*(tot_iou_loss / count) : 0;
            }
            *(l.cost) = avg_iou_loss + classification_loss;
        }


        loss /= l.batch;
        classification_loss /= l.batch;
        iou_loss /= l.batch;

        fprintf(stderr, "v3 (%s loss, Normalizer: (iou: %.2f, obj: %.2f, cls: %.2f) Region %d Avg (IOU: %f), count: %d, class_loss = %f, iou_loss = %f, total_loss = %f \n",
                (l.iou_loss == MSE ? "mse" : (l.iou_loss == GIOU ? "giou" : "iou")), l.iou_normalizer, l.obj_normalizer, l.cls_normalizer, net.index, tot_iou / count, count, classification_loss, iou_loss, loss);

        //fprintf(stderr, "v3 (%s loss, Normalizer: (iou: %.2f, cls: %.2f) Region %d Avg (IOU: %f, GIOU: %f), Class: %f, Obj: %f, No Obj: %f, .5R: %f, .75R: %f, count: %d, class_loss = %f, iou_loss = %f, total_loss = %f \n",
        //    (l.iou_loss == MSE ? "mse" : (l.iou_loss == GIOU ? "giou" : "iou")), l.iou_normalizer, l.obj_normalizer, net.index, tot_iou / count, tot_giou / count, avg_cat / class_count, avg_obj / count, avg_anyobj / (l.w*l.h*l.n*l.batch), recall / count, recall75 / count, count,
        //    classification_loss, iou_loss, loss);

        if(loss != loss) { printf("NaN LOSS detected! No possible to continue!\n"); exit(-7); }
    }
}

void backward_yolo4_layer(const layer l, network net)
{
    axpy_cpu(l.batch*l.inputs, 1, l.delta, 1, net.delta, 1);
}

// Converts output of the network to detection boxes
// w,h: image width,height
// netw,neth: network width,height
// relative: 1 (all callers seems to pass TRUE)
void correct_yolo4_boxes(detection *dets, int n, int w, int h, int netw, int neth, int relative, int letter)
{
    int i;
    // network height (or width)
    int new_w = 0;
    // network height (or width)
    int new_h = 0;
    // Compute scale given image w,h vs network w,h
    // I think this "rotates" the image to match network to input image w/h ratio
    // new_h and new_w are really just network width and height
    if (letter) {
        if (((float)netw / w) < ((float)neth / h)) {
            new_w = netw;
            new_h = (h*netw) / w;
        }
        else {
            new_h = h == 0 ? 0 : neth;
            new_w = h == 0 ? 0 : (w*neth) / h;
        }
    }
    else {
        new_w = netw;
        new_h = neth;
    }
    // difference between network width and "rotated" width
    float deltaw = netw - new_w;
    // difference between network height and "rotated" height
    float deltah = neth - new_h;
    // ratio between rotated network width and network width
    float ratiow = (float)new_w / netw;
    // ratio between rotated network width and network width
    float ratioh = (float)new_h / neth;
    for (i = 0; i < n; ++i) {

        box b = dets[i].bbox;
        // x = ( x - (deltaw/2)/netw ) / ratiow;
        //   x - [(1/2 the difference of the network width and rotated width) / (network width)]
        b.x = (b.x - deltaw / 2. / netw) / ratiow;
        b.y = (b.y - deltah / 2. / neth) / ratioh;
        // scale to match rotation of incoming image
        b.w *= 1 / ratiow;
        b.h *= 1 / ratioh;

        // relative seems to always be == 1, I don't think we hit this condition, ever.
        if (!relative) {
            b.x *= w;
            b.w *= w;
            b.y *= h;
            b.h *= h;
        }

        dets[i].bbox = b;
    }
}

/*
void correct_yolo4_boxes(detection *dets, int n, int w, int h, int netw, int neth, int relative, int letter)
{
    int i;
    int new_w=0;
    int new_h=0;
    if (letter) {
        if (((float)netw / w) < ((float)neth / h)) {
            new_w = netw;
            new_h = (h*netw) / w;
        }
        else {
            new_h = neth;
            new_w = (w*neth) / h;
        }
    }
    else {
        new_w = netw;
        new_h = neth;
    }
    for (i = 0; i < n; ++i){
        box b = dets[i].bbox;
        b.x =  (b.x - (netw - new_w)/2./netw) / ((float)new_w/netw);
        b.y =  (b.y - (neth - new_h)/2./neth) / ((float)new_h/neth);
        b.w *= (float)netw/new_w;
        b.h *= (float)neth/new_h;
        if(!relative){
            b.x *= w;
            b.w *= w;
            b.y *= h;
            b.h *= h;
        }
        dets[i].bbox = b;
    }
}
*/

static int entry_index_y4(layer l, int batch, int location, int entry)
{
    int n =   location / (l.w*l.h);
    int loc = location % (l.w*l.h);
    return batch*l.outputs + n*l.w*l.h*(4+l.classes+1) + entry*l.w*l.h + loc;
}

int yolo4_num_detections(layer l, float thresh)
{
    int i, n;
    int count = 0;
    for(n = 0; n < l.n; ++n){
        for (i = 0; i < l.w*l.h; ++i) {
            int obj_index  = entry_index_y4(l, 0, n*l.w*l.h + i, 4);
            if(l.output[obj_index] > thresh){
                ++count;
            }
        }
    }
    return count;
}

int yolo4_num_detections_batch(layer l, float thresh, int batch)
{
    int i, n;
    int count = 0;
    for (i = 0; i < l.w*l.h; ++i){
        for(n = 0; n < l.n; ++n){
            int obj_index  = entry_index(l, batch, n*l.w*l.h + i, 4);
            if(l.output[obj_index] > thresh){
                ++count;
            }
        }
    }
    return count;
}

void avg_flipped_yolo4(layer l)
{
    int i,j,n,z;
    float *flip = l.output + l.outputs;
    for (j = 0; j < l.h; ++j) {
        for (i = 0; i < l.w/2; ++i) {
            for (n = 0; n < l.n; ++n) {
                for(z = 0; z < l.classes + 4 + 1; ++z){
                    int i1 = z*l.w*l.h*l.n + n*l.w*l.h + j*l.w + i;
                    int i2 = z*l.w*l.h*l.n + n*l.w*l.h + j*l.w + (l.w - i - 1);
                    float swap = flip[i1];
                    flip[i1] = flip[i2];
                    flip[i2] = swap;
                    if(z == 0){
                        flip[i1] = -flip[i1];
                        flip[i2] = -flip[i2];
                    }
                }
            }
        }
    }
    for(i = 0; i < l.outputs; ++i){
        l.output[i] = (l.output[i] + flip[i])/2.;
    }
}

int get_yolo4_detections(layer l, int w, int h, int netw, int neth, float thresh, int *map, int relative, detection *dets, int letter)
{
    //printf("\n l.batch = %d, l.w = %d, l.h = %d, l.n = %d \n", l.batch, l.w, l.h, l.n);
    int i,j,n;
    float *predictions = l.output;
    // This snippet below is not necessary
    // Need to comment it in order to batch processing >= 2 images
    //if (l.batch == 2) avg_flipped_yolo4(l);
    int count = 0;
    for (i = 0; i < l.w*l.h; ++i){
        int row = i / l.w;
        int col = i % l.w;
        for(n = 0; n < l.n; ++n){
            int obj_index  = entry_index(l, 0, n*l.w*l.h + i, 4);
            float objectness = predictions[obj_index];
            //if(objectness <= thresh) continue;    // incorrect behavior for Nan values
            if (objectness > thresh) {
                //printf("\n objectness = %f, thresh = %f, i = %d, n = %d \n", objectness, thresh, i, n);
                int box_index = entry_index(l, 0, n*l.w*l.h + i, 0);
                dets[count].bbox = get_yolo4_box(predictions, l.biases, l.mask[n], box_index, col, row, l.w, l.h, netw, neth, l.w*l.h, l.new_coords);
                dets[count].objectness = objectness;
                dets[count].classes = l.classes;

                for (j = 0; j < l.classes; ++j) {
                    int class_index = entry_index(l, 0, n*l.w*l.h + i, 4 + 1 + j);
                    float prob = objectness*predictions[class_index];
                    dets[count].prob[j] = (prob > thresh) ? prob : 0;
                }
                ++count;
            }
        }
    }
    correct_yolo4_boxes(dets, count, w, h, netw, neth, relative, letter);
    return count;
}

int get_yolo4_detections_batch(layer l, int w, int h, int netw, int neth, float thresh, int *map, int relative, detection *dets, int letter, int batch)
{
    int i,j,n;
    float *predictions = l.output;
    //if (l.batch == 2) avg_flipped_yolo4(l);
    int count = 0;
    for (i = 0; i < l.w*l.h; ++i){
        int row = i / l.w;
        int col = i % l.w;
        for(n = 0; n < l.n; ++n){
            int obj_index  = entry_index(l, batch, n*l.w*l.h + i, 4);
            float objectness = predictions[obj_index];
            //if(objectness <= thresh) continue;    // incorrect behavior for Nan values
            if (objectness > thresh) {
                //printf("\n objectness = %f, thresh = %f, i = %d, n = %d \n", objectness, thresh, i, n);
                int box_index = entry_index(l, batch, n*l.w*l.h + i, 0);
                dets[count].bbox = get_yolo4_box(predictions, l.biases, l.mask[n], box_index, col, row, l.w, l.h, netw, neth, l.w*l.h, l.new_coords);
                dets[count].objectness = objectness;
                dets[count].classes = l.classes;

                for (j = 0; j < l.classes; ++j) {
                    int class_index = entry_index(l, batch, n*l.w*l.h + i, 4 + 1 + j);
                    float prob = objectness*predictions[class_index];
                    dets[count].prob[j] = (prob > thresh) ? prob : 0;
                }
                ++count;
            }
        }
    }
    correct_yolo4_boxes(dets, count, w, h, netw, neth, relative, letter);
    return count;
}

#ifdef GPU

void forward_yolo4_layer_gpu(const layer l, network net)
{
    copy_gpu(l.batch*l.inputs, net.input_gpu, 1, l.output_gpu, 1);

    int b, n;
    for (b = 0; b < l.batch; ++b){
        for(n = 0; n < l.n; ++n){
            int index = entry_index(l, b, n*l.w*l.h, 0);
            activate_array_offset_gpu(l.output_gpu, index, 2*l.w*l.h, LOGISTIC);    // x,y
            if (l.scale_x_y != 1) scal_add_offset_gpu(2*l.w*l.h, l.scale_x_y, -0.5*(l.scale_x_y - 1), l.output_gpu, index, 1); // scale x,y
            index = entry_index(l, b, n*l.w*l.h, 4);
            activate_array_offset_gpu(l.output_gpu, index, (1+l.classes)*l.w*l.h, LOGISTIC); // classes and objectiveness
        }
    }

    if(!net.train || l.onlyforward){
        //opencl_pull_array(l.output_gpu, l.output, l.batch*l.outputs);
        if (l.mean_alpha && l.output_avg_gpu.ptr)  mean_array_gpu(l.output_gpu, l.batch*l.outputs, l.mean_alpha, l.output_avg_gpu);
        opencl_pull_array(l.output_gpu, l.output, l.batch*l.outputs);
        return;
    }

    opencl_pull_array_map(l.output_gpu, net.input, l.batch*l.inputs);
    forward_yolo4_layer(l, net);
    //opencl_push_array(l.output_gpu, l.output, l.batch*l.outputs);
    if(!net.train) return;
    opencl_push_array(l.delta_gpu, l.delta, l.batch*l.outputs);
}
void forward_yolo7_layer_gpu(const layer l, network net)
{
    copy_gpu(l.batch*l.inputs, net.input_gpu, 1, l.output_gpu, 1);

    int b, n;
    for (b = 0; b < l.batch; ++b){
        for(n = 0; n < l.n; ++n){
            int index = entry_index(l, b, n*l.w*l.h, 0);
            if(!l.new_coords){
                activate_array_offset_gpu(l.output_gpu, index, 2*l.w*l.h, LOGISTIC);    // x,y
                index = entry_index(l, b, n*l.w*l.h, 4);
                activate_array_offset_gpu(l.output_gpu, index, (1+l.classes)*l.w*l.h, LOGISTIC); // classes and objectiveness
            }
            if (l.scale_x_y != 1) scal_add_offset_gpu(2*l.w*l.h, l.scale_x_y, -0.5*(l.scale_x_y - 1), l.output_gpu, index, 1); // scale x,y
            
        }
    }

    if(!net.train || l.onlyforward){
        //opencl_pull_array(l.output_gpu, l.output, l.batch*l.outputs);
        if (l.mean_alpha && l.output_avg_gpu.ptr)  mean_array_gpu(l.output_gpu, l.batch*l.outputs, l.mean_alpha, l.output_avg_gpu);
        opencl_pull_array(l.output_gpu, l.output, l.batch*l.outputs);
        return;
    }

    opencl_pull_array_map(l.output_gpu, net.input, l.batch*l.inputs);
    forward_yolo4_layer(l, net);
    //opencl_push_array(l.output_gpu, l.output, l.batch*l.outputs);
    if(!net.train) return;
    opencl_push_array(l.delta_gpu, l.delta, l.batch*l.outputs);
}
void backward_yolo4_layer_gpu(const layer l, network net)
{
    axpy_gpu(l.batch*l.inputs, net.loss_scale*l.delta_normalizer, l.delta_gpu, 1, net.delta_gpu, 1);
}
#endif
